Abstract: Electricity supply has been erratic for a long while in Nigeria. The need for new energy sources had led to a number of alternatives, which have been unaffordable and unavailable due to huge cost and scarcity. In response to this, Fuelless generator was designed and developed using local materials. The driving mechanism of fuelless generator is the 1hp direct current motor, powered by a 12 volts battery, which spines the 0.95KW alternator to produce electricity, while recharging the battery by means of a diode. The fuelless generator has an output of 1KVA; it is pollution-free and eco-friendly. The test unit was built in November, 2014 and has been tested to power offices in the department.
1. ISSN 2393-8471
International Journal of Recent Research in Civil and Mechanical Engineering (IJRRCME)
Vol. 2, Issue 1, pp: (285-289), Month: April 2015 – September 2015, Available at: www.paperpublications.org
Page | 285
Paper Publications
Construction of a Fuel less Generator
1
J.O Otulana, 2
A.A Akinwunmi, 3
J.A Awoyemi, 4
M.B Adeleke,
5
M.I Efunbote Orelaja
Mechanical engineering department Moshood Abiola Polytechnic
Abstract: Electricity supply has been erratic for a long while in Nigeria. The need for new energy sources had led
to a number of alternatives, which have been unaffordable and unavailable due to huge cost and scarcity. In
response to this, Fuelless generator was designed and developed using local materials. The driving mechanism of
fuelless generator is the 1hp direct current motor, powered by a 12 volts battery, which spines the 0.95KW
alternator to produce electricity, while recharging the battery by means of a diode. The fuelless generator has an
output of 1KVA; it is pollution-free and eco-friendly. The test unit was built in November, 2014 and has been
tested to power offices in the department.
Keywords: Dc motor, Alternator, Diode, energy sources, Fuelless generator.
1. INTRODUCTION
In order to find other ways of producing energy, a number of alternatives have been considered. One of these alternatives
is the generation of electricity from a fuelless engine in an isolated power generation system with low maintenance cost.
A fuelless engine produces electricity 24/7 without fuel (petrol, diesel, gas, sun, wind energy).The driving mechanism is
the DC motor, which is driven by a battery (12v). The battery drives the DC motor, which in turn spine the alternator to
produce electricity and at the same time, with the help of the Diode, it recharges back the battery. Fuelless engine has no
negative impact in the environment; it is noiseless, pollution free, self dependent. It can be built to the capacity of the load
you want it to power.
2. MATERIALS AND METHODOLOGY
Materials:
Direct Current Motor: one horse power dc motor
Battery: 12 volts battery, it supplies direct current to the motor.
Alternator: it generates an alternating voltage and current with the aid of capacitor.
Diode: The constant recharging of the battery is done by the diode.
Capacitor: it aids the conversion of energy from the alternator into an alternating voltage.
Ignition key: This is used as an on and off control of the generator system.
Shaft: The shaft is used to transmit toque from DC motor to the alternator.
Cables: Cables are used to transfer current from one source to a load.
2. ISSN 2393-8471
International Journal of Recent Research in Civil and Mechanical Engineering (IJRRCME)
Vol. 2, Issue 1, pp: (285-289), Month: April 2015 – September 2015, Available at: www.paperpublications.org
Page | 286
Paper Publications
Fig 1 Direct current motor Figure 2 Battery
Figure 3 Diode Figure 4 Alternator
Figure 5 ignition Key Figure 6 cables
Figure 7 Shaft
3. ISSN 2393-8471
International Journal of Recent Research in Civil and Mechanical Engineering (IJRRCME)
Vol. 2, Issue 1, pp: (285-289), Month: April 2015 – September 2015, Available at: www.paperpublications.org
Page | 287
Paper Publications
3. METHODS OF CONSTRUCTION
Mounting of the DC motor to alternator
Figure 8 Mounting of the DC motor to alternator
The dc motor has a threaded shaft with locking keys at two sides of the shaft. a rod of 1.5 mm diameter was drilled and
fitted to the shaft, using 10mm gross pin nut. The alternator shaft was welded at a distance of 30mm2
from the gross pin.
The alternator and the dc motor were coupled, using two flat plates of 0.7mm thickness using bolts.
4. FIXING THE MAIN COMPONENTS
Figure 9 Fixing the main components
At the battery head, the positive cable indicated with the red wire will mounted to the positive terminal using battery
terminal plug. This same wire was connected to the key starter where the charges switch will be controlled. And the
battery wire indicate with the black colour was also mounted to the negative terminal of the battery using the same
method. The red and black cables from the battery were connected to the positive and negative part of the dc motor
4. ISSN 2393-8471
International Journal of Recent Research in Civil and Mechanical Engineering (IJRRCME)
Vol. 2, Issue 1, pp: (285-289), Month: April 2015 – September 2015, Available at: www.paperpublications.org
Page | 288
Paper Publications
respectively. At the same time, the red and black wires from the diode were connected to the positive and negative
terminal of the battery respectively. The diode was also connected to the alternator according to the respective charging
outlet on the alternator. Then the load outlet was connected to a wire connected to a bulb for a test run. After test –
running the devices, we found that they are in good condition
Casing and Wiring the Component:
The components were arranged in order and enclosed in a frame. Handles were welded at the top edges .
After we have completed the casing, wiring and appropriate connections required for the generator was done.The power
outlet from the alternator was connected to the load plug indirectly through the circuit switch. The capacitor was also
connected to the capacitor lines coming out of the alternator, the key starter were also mounted at an adjacent position
beside the monitoring board. Then the diode was positioned at a specified place which is suitable for the heat disposal as
a result of the heat sink attached to it.
5. RESULTS
Figure10 Fuelless generator Figure 11 Testing generat
5. ISSN 2393-8471
International Journal of Recent Research in Civil and Mechanical Engineering (IJRRCME)
Vol. 2, Issue 1, pp: (285-289), Month: April 2015 – September 2015, Available at: www.paperpublications.org
Page | 289
Paper Publications
REFERENCES
[1] Abatan O.A, Adewale A.O, and Alabi A.A 2013 Electricity Generation from a Fuelless Engine in an Isolated
Power Generation System IJETAE, Volume 3, Issue 12 pg 701-703.
[2] Bhim singh, SS Murthy and Sushman Gupta 2006, “Analysis and Design of Electronic Load Controller for Self-
Excited Induction Generators” IEE transaction on energy conversion, vol, 21, No. 1, pp 285-293.
[3] Hadi Saada 1999 Power System Analysis Tada McGraw-Hill Publishing Company Ltd.
[4] Hubert, C 1991 Theory Operations, Maintenance of Electrical Machine. Third edition, Prentice Hall, Inc.
[5] MurthyS.S, Malik O. P. and Tandon A. K. 1982, “Analysis of self excited induction generator,” Proc. Inst. Elect.
Eng. C, vol. 129, no. 6, pp. 260–265.
[6] Rabiul Alam M. et al 2011 Single Phase Automatic Voltage Regular Design for Synchronous Generator,
International Journal of Electrical and Computer Sciences IJECS-IJENS Vol 11 No 5.
[7] Raina G. and Malik O. P. 1983, “Wind Energy Conversion Using A Self-Excited Induction Generator,” IEEE Trans.
Power App. Syst., vol.PAS -102, no. 12, pp. 3933–3936.
[8] Theraja B.L. and Theraja A.K. 2007 A Textbook of Electrical Technology 24th Edition, S. Chand and Company Ltd
New Delhi – 110055.
[9] Yonemori H. et al 1996 Next Generation Space Voltage Vector Controlled Three Phase ZVS-PWM active AC – DC
Converter with auxiliary transformer-assisted resonant DC link, International Journal of Electronics, Vol 80, Issue 2.